CH645084A5 - METHOD FOR CONTINUOUSLY PRODUCING A CEMENT CLINKER AND DEVICE FOR CARRYING OUT THE METHOD. - Google Patents

Description

The invention relates to a method for the continuous production of a cement clinker, a cement substance being introduced into a preheating or calcining area; the imported cement material in a predetermined tempera5

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door area is preheated or calcined; the preheated or calcined cement is transferred to a heating area; the preheated or calcined cement material is heated at a predetermined temperature to convert the cement material into a cement clinker; the cement clinker is moved in a cooling area; the cement clinker is cooled to a reduced temperature by means of cooling air; and a part of the exhaust gas flowing from the heating area is passed through the preheating or calcining area. The method and the device for carrying it out are intended for the continuous production of a cement clinker, wherein combustible waste is used as a heat source without generating environmental pollution.

It is known that various combustible waste materials, for example waste tires, organic waste and waste oil, are used to generate heat by decomposing this heat and burning the resulting combustible materials. However, this combustion of the combustible materials causes the creation of an exhaust gas which contains various harmful substances, for example oxides of sulfur, their derivatives, chlorine, chlorine compositions and carbon monoxides. Consequently, in order to prevent pollution due to the harmful exhaust gas, it is necessary to treat the exhaust gas in order to remove the harmful substances or to convert them into harmless substances. However, such treatment requires special treatment facilities and is expensive. In addition, the heat decomposition of the combustible waste materials and the burning of the combustible gas produce various non-combustible residues. It is therefore necessary to treat these residues in such a way that there is no pollution.

These circumstances just mentioned make it very desirable to provide a method and apparatus which process combustible waste without causing pollution.

It has now been recognized by the inventors of the present invention that the combustible waste materials can not only be used as a heat source for producing a cement clinker, but also that the non-combustible, solid residues and the harmful gases generated by the combustible waste are used in this way that they have no adverse effects on the resulting cement clinker.

An object of the present invention is to provide a method and an apparatus for the continuous production of cement clinker, in which combustible waste materials are used as a heat source without generating environmental pollution.

Another object of the present invention is to provide a method and apparatus for continuously producing a cement clinker, in which methods both solid residues and harmful gases are generated from the combustible waste material, but which have no adverse effects on the cement clinker produced , and which are placed in the cement clinker.

These goals are achieved by means of a method of the type mentioned at the outset, which is characterized in that a combustible substance is introduced into a heat decomposition area which is arranged between the heating area and the preheating or calcining area, and a further part of the exhaust gas originating from the heating area in the Heat decomposition area is introduced to perform heat decomposition of the combustible material and generate a combustible gas therefrom; the combustible gas originating from the heat decomposition area is introduced into the preheating or calcining area, and the combustible gas is burned in the preheating or calcining area to preheat or calcine the cement material. The device of the type mentioned at the outset for carrying out the method is characterized by a device which serves to decompose a combustible material by heat, which device is arranged between the preheating or calcining device and the rotary drum furnace and has a heat decomposition chamber which is equipped with a io device is connected, which serves to introduce the heating chamber in the rotary drum furnace and the preheating or calcining chamber combustible material.

The subject matter of the invention is explained in more detail below with reference to the drawings, for example. Show it; Fig. 1 15 to 6 simplified sections through various embodiments of devices designed according to the invention.

When, for example, the method according to the invention is carried out, a cement material is introduced into a preheating or calcining area and preheated, for example, to a temperature of 600 ° C. to 1000 ° C. or calcined, for example, in a temperature range from 800 ° C. to 1200 ° C. The preheated or calcined cement material is fed to a heating area in a rotary drum kiln and converted into cement clinker at a temperature range of 25, for example 1000 to 1500 ° C. The cement material is additionally heated and calcined in the heating area and subsequently the calcined cement material is sintered in order to produce the cement clinker. The resulting cement clinker 30 is then fed to a cooling area and cooled to a desired temperature, for example from 70 to 150 ° C. In the method just mentioned, an exhaust gas which is generated in the heating region has a temperature in the range from 800 ° C. to 1200 ° C., which temperature value is sufficient to subject flammable substances, for example waste tires, to thermal decomposition. This exhaust gas flows into the preheating or calcining area in order to preheat or calcine the material contained therein.

In the method of the present invention, it is important 40 that a combustible material, such as combustible waste such as waste tires, organic waste or oil waste, oil shale, be introduced into a heat decomposition area located between the preheating or calcining area and the heating area, at least one Part 45 of the exhaust gas emerging from the heating area is introduced into the heat decomposition area in order to decompose the combustible material at elevated temperature by heat and to produce a combustible gas from the combustible material. The combustible gas is introduced from the heat decomposition area into the preheating or calcining area and burned therein to preheat or calcine the cement.

In this process, a solid residue, i.e. a residue in the form of solids, which has been generated by the combustible material in the heat decomposition area, is mixed with the preheated or calcined cement material and the resulting mixture is moved into the heating area. The solid residue described contains, for example, metals, for example iron, carbon 60, SiCh, CaO, Al2O3, and Fe203. These materials are heated together with the cement material at an elevated temperature in the heating area, and the resulting products, which have no harmful effect on the cement clinker, are uniformly distributed in the resulting cement clinker.

In addition, part of the exhaust gas that has been generated from the combustible gas in the preheating or calcining area, for example oxides of sulfur,

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vate, chlorine, chlorine compounds (HCl), and carbon monoxide, which are harmful to humans, with part (CaO) of the cement material in the preheating or calcining area, and the resulting reaction product is introduced into the cement material.

The following combustible materials can be used to practice the present invention: waste tires, rubber wastes, oil wastes, oily sludges, asphalt wastes, tar and bitumen wastes, digested sludge, rubble and organic waste. Flammable substances can be oil shale, oily sand, coal, lignite and peat.

When the cement clinker is supplied from the heating area in the rotary drum furnace to the cooling area, cooling air is introduced into this cooling area in order to cool the cement clinker. The exhaust air from this cooling area has a temperature in the range from 100 to 800 ° C., which temperature is sufficiently high that the combustible materials, for example oil waste, oil-containing sludge, polyethylene or polyvinyl chloride, decompose thermally. In addition, the exhaust air contains 15 molar% oxygen, while the exhaust gas from the heating area contains only 0.5 to 3.5 molar% oxygen. Thus, the exhaust air coming from the cooling area can be used not only to thermally decompose the combustible material, but also to burn part of the combustible material in such a way that its heat decomposition is accelerated, ie that part of the exhaust air is preheated - Or calcining can be introduced to support the combustion of the combustible gas present therein. A further part of the exhaust air originating from the cooling area can also be introduced into the heat decomposition area in order to support the heat decomposition of the combustible material. Because the exhaust air now contains molecular nitrogen, some of the combustible material can be burned in the heat decomposition area, so that the heat decomposition of the combustible material can be accelerated.

Exhaust gas from the calcining area can be used to preheat the cement. The cement can be in the form of granules or fine particles.

The combustible material can be introduced continuously or intermittently into the heat decomposition area. However, it is preferable to introduce the combustible material intermittently into the heat decomposition area so that the preheating or calcining temperature can be controlled. It is therefore preferable that the supply and the supply amount of the combustible substance are controlled depending on the temperature of a part of the preheating or calcining area in which part the combustible gas is burned. If the temperature falls below a predetermined value, the combustible material is supplied and / or the quantity of the combustible material is increased.

This control means that the temperature of the preheating or calcining area can be kept largely uniform during the entire period of cement clinker production.

In order to flow the exhaust gas from the heating area through the preheating or calcining area, a negative pressure can be generated in or upstream of the preheating or calcining area.

The exemplary embodiment of the device according to the invention has a device for supplying a cement material; has a preheating or calcining device which contains a preheating or calcining chamber in which the cement material supplied is preheated or calcined; there is also a rotary drum kiln which has a heating chamber in which the preheated or calcined cement material is converted into cement clinker, there is a cooling device which contains a cooling chamber for the cement clinker and there is also an air blower device which serves to introduce cooling air into the cooling chamber therethrough and there is a flow-generating device which serves to cause the exhaust gas to flow from the heating chamber through the preheating or calcining chamber.

In the device, it is important that the heat decomposing device having a heat decomposing chamber is arranged between the preheating or calcining device and the rotary drum furnace. The heat decomposition device has a supply device for a combustible substance and is connected to the heating chamber and the preheating or calcining chamber.

The heat decomposition chamber can be connected to the device for supplying the combustible material by means of a line. In this case, the combustible material is introduced into the heat decomposition chamber through this line. Furthermore, the heat decomposition device can additionally be provided with an exhaust gas line which runs from a lower section of the heat decomposition chamber to the heating chamber of the rotary drum furnace. This line serves to introduce part of an exhaust gas from the heating chamber into the heat decomposition chamber.

Furthermore, the heat decomposition device can be provided with a line for combustible gas, which runs from an upper section of the heat decomposition chamber into the preheating or calcining chamber. This line serves to introduce the combustible gas, which has been generated by the thermal decomposition of the combustible material, into the preheating or calcining chamber, in which chamber the combustible gas is burned.

If the combustible material is in the form of lumps or shaped objects, for example waste tires, it is preferable to arrange a grate in the heat decomposition chamber in such a way that such combustible material can be placed on this grate. When the combustible is heat-decomposed, the resulting combustible gas is separated from the solid residues remaining on the grate, and these solid residues are supplied from the grate against the heating chamber of the rotary drum furnace through the exhaust pipe.

The cooling chamber can be connected to the preheating or calcining chamber by means of an exhaust air line. This line serves to supply part of an exhaust air from the cooling chamber to the preheating or calcining chamber. This exhaust air can support the burning of the combustible gas in the preheating or calcining chamber.

In addition, the exhaust duct may be connected to a lower portion of the heat decomposition chamber by branching a duct from the exhaust duct.

The device which serves to convey the exhaust gas from the heating chamber of the rotary drum furnace through the preheating or calcining chamber can be a blower which is arranged inside or upstream of the preheating or calcining chamber.

The description of the invention, for example, will now be continued with reference to the attached drawing figures.

1 shows a device 1 for producing cement clinker, which contains a cement supply device 2, a preheater 3, a rotary drum furnace 4 and a cooler 5. Cement 6 is granulated in a granulator 7, i.e. made fine-grained. The granulated cement material is introduced into the preheater 3 by means of an endless conveyor 8. The preheater 3 has a first preheating chamber 9, a second preheating chamber 10 and

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a third preheating chamber 10a, which chamber is separated from each other by means of partitions 11a and 11b. The cement material 6 supplied to the preheater 3 passes through the first, second and third preheating chambers 9, 10 and 10a by means of an endless conveyor 12. In the third preheating chamber 10a, a partition wall 1 lc projects downward from the ceiling of the third chamber 10a, such that the third Chamber 10a is divided into two sections, ie, a first section 10b and a second section 10c.

The preheated (calcined) cement material 6 is then fed to a heating chamber 13 in the rotary drum furnace 4 via an obliquely arranged guide plate 14. In the heating chamber 13, the cement material 6 is transformed into cement clinker. The cement clinker 15 thus produced is discharged from the heating chamber 13 into a cooling chamber 16 of the cooler 5, in which cooler 5 it is cooled by means of cooling air which is introduced from the environment by means of an air blower device, which device has an inclined plate 35, in a number of holes are formed, at least one air chamber 36 and at least one blower 37 being connected to each air chamber 36 by means of a line 38.

The cement material supplied to the heating chamber 13 is produced by means of a combustible gas with a burner 17 in which a mixture of a fuel and air is burned. The cooling air supplied to the cooling chamber also acts as secondary air to support the combustion of the air-fuel mixture.

The device 1 according to FIG. 1 has a heat decomposition device 18 for a combustible substance 19. The heat decomposition device 18 has a heat decomposition chamber 20 and a feed device 21 for the combustible substance 19. This supply device 21 is connected by means of a line 22 to the heat decomposition chamber, which line 22 has one or more air flaps. A grate 24 is arranged in the heat decomposition chamber 20. A lower section of the heat decomposition chamber 20 is connected to an exhaust pipe 25, which runs into the second section 10c of the third preheating chamber 10a and against the heating chamber 13. An upper section of the heat decomposition chamber 20 is connected to a line 26 for combustible gases, which line 26 runs in the first section 1 whether the third preheating chamber 10a of the preheater 3.

The combustible substance 19 can be introduced intermittently into the heat decomposition chamber 20 from the supply device 21 by opening the airtight flaps 23 in the line 22. The combustible substance 19, which lies on the grate 24 in the heat decomposition chamber 20, is heat decomposed by the exhaust gas, which is introduced into the heat decomposition chamber 20 from the heating chamber 13 through the exhaust pipe 25. The resulting combustible gas is introduced through line 26 into the first section 10b of the third preheating chamber 10a and is burned in the first section 10b such that the cement material is preheated. A portion of the preheating gas present in the third chamber 10a is drawn off by generating a negative pressure through a manifold 18 and a suction line 29 by means of a blower 27, and then this is blown into the second preheating chamber 10 through a line 30. A portion of the exhaust gas from the first chamber 9 and second chamber 10 is drawn off by generating a vacuum in a manifold 32 and a line 33 by means of a blower 31 and this is then discharged to the outside through a line 34 from the device 1. The partition 11c in the third preheating chamber 10a serves as a guide plate for uniformly introducing the exhaust gas from the heating chamber 13 of the rotary drum furnace 4 into the exhaust pipe 25 and the manifold 28 and for direct introduction of the combustible gas present in the first section 10b to prevent in the manifold 28. Part of the combustible gas which is introduced into the first section 10b and part of the resulting exhaust gas which is generated in the section 10b are introduced through lines 39 and 39e into the second preheating chamber 10, around that in the second chamber Preheat 10 existing cement.

The device 41 of FIG. 2 has a suspension preheater 42, has a calciner 43 with a calcining chamber 58, contains a rotary drum furnace 4, a cooler 5 and a heat decomposition device 18.

In this device 41, part of the exhaust gas from the heating chamber 13 of the rotary drum furnace 4 is introduced into the heat decomposition device 18 and another part of this exhaust gas is introduced into a calcining chamber 58 through a line 44 and a mixing chamber 60. Exhaust gas originating from the calcining chamber 58 is released to the outside by the device 41, this exhaust gas being passed through a cyclone separator 45, a line 46, a cyclone separator 47, a line 48, a cyclone separator 49, a line 50, a cyclone separator 51 and lines 52 and 53 flows, the conveying being carried out by means of a blower 54.

A cementitious material is introduced through an inlet 55 and moves against the calcining chamber 58 such that the cementitious material which is supplied through the inlet 55, together with a flow of the exhaust gas through the line 50, is supplied to the cyclone separator 51, the cement material in the cyclone separator 51 is separated from the flow of the exhaust gas, then the separated cement is brought through a line 56 into the line 48, is fed together with a mass flow of the exhaust gas through the line 48 to the cyclone separator 49, is separated therein from the mass flow of the exhaust gas, the separated one Cement is fed through a line 57 into line 46, is brought together with a mass flow of the exhaust gas through line 46 into the cyclone separator 47 and is separated from the exhaust gas in this cyclone separator 47 and the separated cement material is then introduced into the calcining chamber 58. As it moves from the inlet 55 to the calcining chamber 58, the cement is preheated by the various flows of the exhaust gas, which flows through lines 50, 48 and 46.

The combustible material 19 disposed in the heat decomposition chamber 20 is heat decomposed by the exhaust gas introduced into the chamber 20 through the pipe 25, and the resulting combustible gas is introduced into the calcining chamber 58 through the pipe 26. The combustible gas is burned in the calcining chamber 58, so that the cement material is calcined. The calcined cement material is brought into the cyclone separator 45 and separated therein from the flow of the exhaust gas, and the separated cement material is introduced into the rotary drum furnace 4 through the line 59.

In the device 41 according to FIG. 2, the cooling chamber 16 is connected to a mixing chamber 60, which mixing chamber 60 is formed in the line 44 between the calcining chamber 58 and the heating chamber 16, for which purpose a line 61 is arranged. A portion of the exhaust air from the cooling chamber 16 is introduced into the mixing chamber 60 and mixed with the exhaust gas from the heating chamber 13. This gas mixture is introduced into the calcining chamber 58. A cyclone separator 62 is used to separate the exhaust air from dust. The separated dust becomes s

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returned to the cooling chamber and mixed with the cement clinker.

Reference is now made to FIG. 3. Here, a device 71 has a heat decomposition device 72 which is arranged between the heating chamber 13 and the calcining chamber 58 and which has a heat decomposition chamber 73 which is arranged immediately upstream of the heating chamber 13. The heat decomposition chamber 73 is connected by a line 74 to the supply device 21 for the combustible material. Accordingly, a combustible substance 19, which is preferably in the form of lumps or solid objects, for example waste tires, is introduced through line 74 from supply device 21 into heat decomposition chamber 73. In this case, the entire amount of the exhaust gas from the heating chamber is introduced into the heat decomposition chamber 73 to decompose the combustible substance 19 into heat, and the resulting combustible gas is introduced into the calcining chamber 51 together with the exhaust gas. The combustible gas and the exhaust gas can be mixed with exhaust air which has been introduced from the cooling chamber 16 through the line 61 into the mixing chamber 60.

It is preferable to control the amount of the combustible material that is brought into the heat decomposition chamber 73

is controlled to such an extent that the amount of thermal energy generated from the combustible gas is approximately 10% or less than the total amount of thermal energy that is necessary to transform the calcined cement material into the desired cement clinker. It is also preferable that the intermittent feeding and the feeding amount of the combustible material are controlled depending on the temperature in both the heating chamber 13 and the calcining chamber 58.

Reference is now made to FIG. 4. The device 81 shown therein has a heat decomposition device 18 in which a lower part of the heat decomposition chamber 20 is connected to the mixing chamber 60 by means of a line 82.

In the device 81 of FIG. 4, a larger part of the exhaust gas is introduced into the mixing chamber 60 and mixed therein with the exhaust air which is introduced through the line 61 from the cooling chamber 16.

A part of the gas mixture is introduced into the heat decomposition chamber 20 and the remaining part is introduced into the calcining chamber 58. The part of the gas mixture present in the heat decomposition chamber 20 can not only decompose the combustible substance 19 by heat, but also can burn part of the combustible substance such that the heat decomposition is promoted. The resulting mixture of combustible gas and exhaust gas is introduced into the calcining chamber 58 through a line 83 and burned therein in order to calcine the cement material.

Reference is made to FIG. 5. The device 91 shown therein has a heat decomposition device 92, which is connected by means of a line 24 to a supply source 93 for combustible material. In this case, it is preferred that the combustible be in the form of a liquid or slurry, such as oil waste, oil-containing sludge, or any other liquid organic mixture, batch or composition.

The exhaust gas from the heating chamber 13 of the rotary drum furnace 4 is introduced into the heat decomposition chamber 92. Furthermore, the exhaust air originating from the cooling chamber 16 is introduced into the heat decomposition chamber 92 through the line 61. The combustible material that is introduced into the heat decomposition chamber 92 is by the

Mixture of exhaust gas from the heating chamber 13 and the exhaust air from the cooling chamber 16 are heat-decomposed, and the resulting heat-decomposing mixture is introduced into the calcining chamber 58 and burned therein to calcine the cement.

Reference is now made to FIG. 6. This device 101 has a heat decomposition device 102 which has a heat decomposition chamber 103 and which has a line 104 by means of which the calcining chamber 105 is connected directly to the cooling chamber 16. The heat decomposition chamber 103 has a line 106 for combustible gas, by means of which an upper part of the heat decomposition chamber 103 is connected to the calcining chamber 105 and has an exhaust pipe 107, which runs from a lower part of the heat decomposition chamber 103 against the heating chamber 13 of the rotary drum furnace 4. Furthermore, a lower part of the decomposition chamber 103 is connected to the exhaust air line 104 by means of a line 108.

The device 101 also has a first preheater 109 and a second preheater 110, which are arranged parallel to one another. In the first preheater 109, exhaust gas flows upward from the heating chamber 13 through a line

111, a cyclone separator 112, a line 113, a cyclone separator 114, a line 115, a cyclone separator 116, a line 117, a cyclone separator 118 and a line 119 and is then discharged to the outside by means of a blower 120 from the device 101. In the first preheater 109, the cement material is introduced through a first inlet 121, moves together with the flow of the exhaust gas through the line 117 into the cyclone separator 118 and is separated from the exhaust gas flow in the cyclone separator 118; the separated cement is moved through line 122 into line 115 and moves along with a flow of the exhaust gas through the line

115 in the cyclone separator 116, and is separated in the cyclone separator 116 from the flow of the exhaust gas; the separated cement material is brought into line 113 through a line 123, moves together with an exhaust gas flow through line 113 to the cyclone separator 114, and is separated from the exhaust gas flow in the cyclone separator 114; the separated cement material is introduced through line 124 into line 111, moves together with an exhaust gas flow through line 111 to the cyclone separator

112, and is separated from the exhaust gas flow in the cyclone separator 112 and the separated cement material is then introduced into the calcining chamber 105 through a line 125. While the cement material is being conveyed from the inlet 121 to the calcining chamber 105, the cement material is preheated by the exhaust gases that come from the heating chamber 13.

In the second preheater 110, an exhaust gas that comes from the calcining chamber 105 will flow upward and this through a line 126, a cyclone separator 127, a line 128, a cyclone separator 129, a line 130, a cyclone separator 131, a line 121, one Cyclone separator 133 and a line 134 and is then discharged from the device 101 to the outside by means of a fan 135. The flow of exhaust gas from the calcining chamber 105 is used to preheat the cement.

The cement material is introduced into line 132 through a second inlet 136, moves together with a flow of the exhaust gas through line 132 to the cyclone separator 133, is separated from the flow of the exhaust gas in the cyclone separator 133; the separated cement is introduced through line 137 into line 130, moves along with a flow of the exhaust gas through line 130 and to the cyclone separator 133, and is separated from the flow of the exhaust gas in the cyclone separator 131;

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the separated cement material is fed through line 138 into line 128, moves together with a flow of the exhaust gas through line 128 to cyclone separator 129 and is separated from the exhaust gas flow in cyclone separator 129; finally the separated cement material is introduced into the calcining chamber 105 through a line 139.

Now, when the cement material is calcined in the calcining chamber 105 by burning the combustible gas that comes from the heat decomposition chamber 103, the resulting calcined material together with a flow of the exhaust gas from the calcining chamber 105 is fed to the cyclone separator 125 and through it Exhaust gas stream separated. The separated cement material is introduced into the heating chamber 13 through a line 140. The calcining chamber 15 can be equipped with an additional burner (not shown in FIG. 6) in order to burn any fuel in this calcining chamber. This additional burner would serve to support and accelerate the calcining of the cement material.

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Claims (20)

645 084 2nd PATENT CLAIMS 1. A method for continuously producing a cement clinker, wherein a cement material is introduced into a preheating or calcining area, the introduced cement material is preheated or calcined in a predetermined temperature range, the preheated or calcined cement material is transferred into a heating area which preheated or calcined cement material is heated to a predetermined temperature in order to convert the cement material into a cement clinker, the cement clinker is moved into a cooling area, the cement clinker is cooled to a reduced temperature by means of cooling air, and a part of the exhaust gas flowing from the heating area through the preheating or calcining area, characterized in that a combustible material is introduced into a heat decomposition area which is arranged between the heating area and the preheating or calcining area, a further part of the exhaust gas originating from the heating area into the heat decomposition is introduced to perform heat decomposition of the combustible material and generate a combustible gas therefrom, the combustible gas originating from the heat decomposition region is introduced into the preheating or calcining region, and the combustible gas is burned in the preheating or calcining region to preheat the cement substance or to calcine. 2. The method according to claim 1, characterized in that the combustible material at least one selected member of the group waste tires, rubber waste, oil waste, oil-containing sludge, asphalt waste, tar and bitumen waste, oil shale, oil-containing sand, waste organic composition, coal, lignite, Contains peat, digested sludge and rubble. 3. The method according to claim 1, characterized in that the exhaust gas introduced from the heating area into the heat decomposition area has a temperature of 100-1100 ° C. 4. The method according to claim 1, characterized in that a part of the exhaust air from the cooling area is introduced into the preheating or calcining area in order to support the combustion of the combustible gas. 5. The method according to claim 4, characterized in that the exhaust gas originating from the heating area is mixed in a mixing area with the exhaust air originating from the cooling area, which is arranged between the heating area and the preheating or calcining area, and that the mixture in the preheating or calcining area is introduced. 6. The method according to claim 1, characterized in that the combustible material is introduced intermittently into the heat decomposition area. 7. The method according to claim 1, characterized in that the introduction and the introduced amount of the combustible substance is controlled depending on the temperature of a part of the preheating or calcining area in which part the combustible gas is burned. 8. The method according to claim 1, characterized in that part of the combustible material is burned in the heat decomposition area. 9. The method according to claim 1, characterized in that a solid residue, which has been generated in the heat decomposition area from the combustible material, is mixed with the preheated or calcined cement material, whereupon the mixture is moved into the heating area. 10. The method according to claim 1, characterized in that a part of the exhaust gas generated from the combustible gas is reacted in the preheating or calcining area with a part of the cement substance and the substance formed from the reaction is introduced into the cement substance. 11. The method according to claim 1, characterized in that the cement material is preheated by means of an exhaust gas originating from the calcining area. 12. The apparatus for carrying out the method according to claim 1, with a device for supplying a cement material, a device for preheating or calcining the cement material, which device has a preheating or calcining chamber which is arranged downstream of the supply device, a rotary drum furnace which serves to convert the cement material into a cement clinker, which rotary drum furnace has a heating chamber, which is arranged downstream of the preheating or calcining device, with a device for cooling the cement clinker with air, which device has a cooling chamber and air blower device arranged downstream of the rotary drum furnace, and one Device which serves to pass exhaust gas flowing from the heating chamber through the preheating or calcining chamber, characterized by a device which serves to decompose a combustible material by heat, which device between the preheating or calcining device and is arranged in the rotary drum furnace and has a heat decomposition chamber which is connected to a device which serves to introduce combustible material into the heating chamber in the rotary drum furnace and the preheating or calcining chamber. 13. The apparatus according to claim 12, characterized in that the heat decomposition device has a line by means of which the heat decomposition chamber is connected to the device for supplying combustible material. 14. The apparatus according to claim 12, characterized in that the heat decomposition device has a grate for receiving the combustible material. 15. The apparatus according to claim 12, characterized in that the heat decomposition device has an exhaust gas line which runs from a lower portion of the heat decomposition chamber against the heating chamber of the rotary drum furnace. 16. The apparatus according to claim 12, characterized in that the heat decomposition device has a conduit for combustible gas which extends from an upper portion of the heat decomposition chamber into the preheating or calcining chamber. 17. The apparatus according to claim 12, characterized in that the cooling chamber is connected to the preheating or calcining chamber by means of an exhaust air line. 18. The apparatus according to claim 17, characterized in that the exhaust air line is additionally connected to the heat decomposition chamber by means of the heat exhaust gas line. 19. The apparatus according to claim 17, characterized in that the exhaust line is additionally connected to a lower section of the heat decomposition chamber by a line branched from it. 20. The apparatus according to claim 17, characterized in that the exhaust air line is connected to a mixing chamber which is arranged in a line between the heating chamber and the preheating or calcining chamber.